EP0472578B1 - Apparatus and methods for the generation of stabilised images from waveforms - Google Patents

Apparatus and methods for the generation of stabilised images from waveforms Download PDF

Info

Publication number
EP0472578B1
EP0472578B1 EP90907345A EP90907345A EP0472578B1 EP 0472578 B1 EP0472578 B1 EP 0472578B1 EP 90907345 A EP90907345 A EP 90907345A EP 90907345 A EP90907345 A EP 90907345A EP 0472578 B1 EP0472578 B1 EP 0472578B1
Authority
EP
European Patent Office
Prior art keywords
waveform
stabilised
sound wave
peaks
summation output
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
EP90907345A
Other languages
German (de)
French (fr)
Other versions
EP0472578A1 (en
Inventor
Roy Dunbar Patterson
John Wilfred Holdsworth
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Medical Research Council
Original Assignee
Medical Research Council
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Medical Research Council filed Critical Medical Research Council
Publication of EP0472578A1 publication Critical patent/EP0472578A1/en
Application granted granted Critical
Publication of EP0472578B1 publication Critical patent/EP0472578B1/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • GPHYSICS
    • G10MUSICAL INSTRUMENTS; ACOUSTICS
    • G10LSPEECH ANALYSIS TECHNIQUES OR SPEECH SYNTHESIS; SPEECH RECOGNITION; SPEECH OR VOICE PROCESSING TECHNIQUES; SPEECH OR AUDIO CODING OR DECODING
    • G10L21/00Speech or voice signal processing techniques to produce another audible or non-audible signal, e.g. visual or tactile, in order to modify its quality or its intelligibility
    • G10L21/06Transformation of speech into a non-audible representation, e.g. speech visualisation or speech processing for tactile aids
    • GPHYSICS
    • G10MUSICAL INSTRUMENTS; ACOUSTICS
    • G10LSPEECH ANALYSIS TECHNIQUES OR SPEECH SYNTHESIS; SPEECH RECOGNITION; SPEECH OR VOICE PROCESSING TECHNIQUES; SPEECH OR AUDIO CODING OR DECODING
    • G10L25/00Speech or voice analysis techniques not restricted to a single one of groups G10L15/00 - G10L21/00
    • G10L25/48Speech or voice analysis techniques not restricted to a single one of groups G10L15/00 - G10L21/00 specially adapted for particular use

Definitions

  • the invention relates to apparatus and methods for the generation of stabilised images from waveforms. It is particularly applicable to the analysis of non-sinusoidal waveforms which are periodic or quasi-periodic.
  • Analysis of non-sinusoidal waveforms is particularly applicable to sound waves and to speech recognition systems.
  • Some speech processors begin the analysis of a speech wave by dividing the speech wave into separate frequency channels, either using Fourier Transform methods or a filter bank that mimics that encountered in the human auditory system to a greater or lesser degree. This is done in an attempt to make the speech recognition system noise resistant.
  • the speech wave is divided into channels by filters operating in the time domain, and the result is a set of waveforms each of which carries some portion of the original speech information.
  • the temporal information in each channel is analysed separately and is usually divided into segments and an energy value for each segment determined so that the output of the filter bank is converted into a temporal sequence of energy values.
  • the segment duration is typically in the range 10-40 ms.
  • the integration is insensitive to periodicity in the information in the channel and again fine grain temporal information in the speech wave is destroyed before it has been completely analysed. At the same time with regard to detecting signals in noise, the segment durations referred to above are too short for sufficient integration to take place.
  • the temporal integration of a non-sinusoidal waveform is a data-driven process and one which is sensitive and responsive to periodic characteristics of the waveform.
  • the present invention is particularly suited to the analysis of sound waves.
  • the invention is applicable to the analysis of sound waves representing musical notes or speech.
  • the invention is particularly useful for a speech recognition system in which it may be used to assist pitch synchronous temporal integration and to distinguish between periodic signals representing voiced parts of speech and aperiodic signals which may be caused by noise.
  • the invention may be used to assist pitch synchronous temporal integration generating a stabilised image or representation of a waveform without substantial loss of temporal resolution.
  • the stabilised image of a waveform referred to herein is a representation of the waveform which retains all the important temporal characteristics of the waveform and is achieved through triggered temporal integration of the waveform as described herein.
  • the present invention seeks to provide apparatus and methods for the generation of a stabilised image from a waveform using a data-driven process and one which is sensitive and responsive-to periodic characteristics of the waveform.
  • the present invention provides a method of generating a stabilised image from a waveform, which method comprises detecting peaks in said waveform, in response to detecting peaks sampling successive time extended segments of said waveform, and forming a summation output by summing first signals representing each successive segment with second signals representing an attenuated summation output formed by previous segments of said waveform, whereby said summation output forms a stabilised image of said waveform.
  • the present invention further provides a method wherein the summation output is reduced by time dependant attentuation to form the attenuated summation output.
  • a first limit of the time extended segments of said waveform is determined by the detection of peaks in said waveform and either a second limit of the time extended segments of said waveform is a predetermined length of time after the first limit of the time extended segments of said waveform or a second limit of the time extended segments of said waveform is determined by the detection of peaks in said waveform.
  • the present invention provides for the analysis of a non-sinusoidal sound wave a method which further includes the spectral resolution of a waveform into a plurality of filtered waveforms each filtered waveform independantly having a stabilised image generated.
  • said method further comprises the extraction of periodic characteristics of the sound wave and the extraction of timbre characteristics of the sound wave.
  • a second aspect of the present invention provides apparatus for generating a stabilised image from a waveform comprising (a) a peak detector for receiving and detecting peaks in said waveform, (b) means for sampling successive time extended segments of said waveform, said sampling means being coupled to said peak detector, (c) summing means for summing first signals representing each successive time extended segment with second signals to form a summation output, said second signals representing an attenuated summation output, said summing means being coupled to said sampling means, and (d) feedback means for attenuating said summation output to derive said second signals from said summation output, said feedback means being coupled to said summing means, whereby said summation output forms a stabilised image of said waveform.
  • the present invention provides speech recognition apparatus including apparatus as described above together with means for providing auditory feature extraction from analysis of the filtered waveforms together with syntactic and semantic processor means providing syntactic and semantic limitations for use in speech recognition of the sound wave.
  • Temporal integration of a waveform is necessary when analysing the waveform in order to identify more clearly dominant characteristics of the waveform and also because without some form of integration the output data rate would be too high to support a real-time analysis of the waveform. This is of particular importance in the analysis of sound waves and speech recognition.
  • FIG. 1 a schematic diagram of a stabilised image generator is shown which may be used to temporally integrate the output of a channel of a filterbank.
  • the integration carried out by the stabilised image generator is triggered and quantised so that loss of temporal resolution from the integration is avoided.
  • a stabilised image generator may be provided for each channel of the filterbank.
  • the stabilised image generator has a peak detector (2) coupled to sampling means in the form of a buffer (1) and a gate (3) or other means for controlling the coupling between the buffer (1) and a summator (4) or other combining means.
  • the gate (3) and summator (4) form part of an integration device (5).
  • the summator (4) is also coupled to a decay device (6) and forms a feedback loop with the decay device (6) in the integration device (5).
  • the output of the summator (4) is coupled to the input of the decay device (6) and the output of the decay device (6) is coupled to an input of the summator (4).
  • the decay device derives the second input into the summator (4) from the output of the summator (4).
  • the decay device (6) is also coupled to the peak detector (2).
  • the summator (4) has two inputs, a first input which is coupled to the gate (3) and a second input which is coupled to the output of the decay device (6).
  • the two inputs receive an input each from the gate (3) and the decay device (6) respectively.
  • the two inputs received are then summed by the summator (4) and the summation output of the summator (4) is the resultant summed inputs and is a stabilised image of the input into the buffer (1).
  • the summation output of the summator (4) is also coupled to a contour extractor (7) which temporally integrates over the stabilised image from the summator (4) and which has a separate output.
  • the period of a sound wave is represented schematically as a pulse stream in Figures 4a and 5a having a period of 8 ms and with just over 6 cycles shown.
  • Figures 4b and 5b show schematically the output of three channels of a filterbank in response to the sound wave, the three channels having centre frequencies in the region of the second, fourth and eighth harmonics of the sound wave.
  • the first pulse in each cycle is labelled with the cycle number and the harmonics are identified on the left hand edge of Figures 4b and 5b.
  • the time axes are the same in Figures 4a, 4b, 5a and 5b.
  • the output of the channel in the form of a pulse stream or waveform is input into the stabilised image generator through the buffer (1) and separately into the peak detector (2).
  • the buffer (1) has a fixed size of 20 ms and there is a time delay mechanism whereby the peak detector (2) receives the pulse stream approximately 20 ms after the pulse stream was initially received by the buffer (1).
  • the buffer (1) is transparent and retains the most recent 20 ms of the pulse stream received.
  • the peak detector (2) detects major peaks in the pulse stream and on detection of a major peak issues a trigger to the gate (3).
  • the gate (3) When the gate (3) receives a trigger from the peak detector (2) the gate (3) opens to allow the contents of the buffer (1) at that instant to be read by the first input of the summator (4). Once the contents of the buffer (1) has been read by the summator (4) the gate (3) closes and the process continues until a further trigger is issued from the peak detector (2) when the gate (3) opens again and so on.
  • the contents of the buffer (1) read by the first input of the summator (4) is added to the input pulse stream of the second input of the summator (4).
  • the output of the summator (4) is the resultant summed pulse stream. Initially, there is no pulse stream input to the second input of the summator (4) and the output of the summator (4) which is the summed pulse stream is the same as the pulse stream received from the buffer (1) by the first input of the summator (4).
  • the second input of the summator (4) is coupled to the output of the decay device (6) and in turn the input of the decay device (6) is coupled to the output of the summator (4); thus after the initial output from the summator (4) the second input of the summator (4) has an input pulse stream which is the same as the output of the summator (4) except that the pulse stream has been attenuated.
  • the decay device (6) has a predetermined attenuation such that it is sufficiently slow that the stabilised image will produce a smooth change when there is a smooth transition in the pulse stream input into the buffer (1). If however, the periodicity of the pulse stream input into the buffer (1) remains the same the stabilised image is strengthened over an initial time period for example 30 ms and then asymptotes to a stable form over a similar time period such that the pulse stream input into the first input of the summator (4) is equal to the amount the summed pulse stream is attenuated by the decay device (6).
  • the resultant stabilised image has a greater degree of contrast relative to the pulse stream input into the buffer.
  • the pulse stream into the first input of the summator (4) is set to zero then the summator (4) continues to sum the two inputs, and the stabilised image gradually decays down to zero also.
  • the predetermined attenuation is proportional to the logarithm of the time since the last trigger was issued by the peak detector (2) and the issuance of a trigger by the peak detector (2) may be noted by the decay device (6) through its coupling with the peak detector (2) though this is not necessary.
  • the 't' marker on Figure 4b at about 20 ms indicates the detection point of the peak detector (2) relative to the pulse stream being received by the buffer (1).
  • the contents of the buffer (1) being retained at that moment is the pulse stream appearing between the 't' marker and the far right of the diagram at 0 ms.
  • the upward strokes on certain peaks of the pulse stream of the eighth harmonic indicate previous peaks detected for which triggers were issued by the peak detector (2).
  • Figure 4c shows schematically the contents of the buffer (1) when the most recent trigger was issued by the peak detector (2). As may be seen by referring back to Figure 4b for the eighth harmonic the previous trigger occurred in the fourth cycles and is shown in Figure 4c.
  • the fifth and sixth cycle of the pulse stream were also contained in the buffer (1). when the trigger was issued and they are also shown.
  • Figure 4c shows the contents of three buffers for the three channels when the most recent triggers were issued by the corresponding peak detectors. It may be seen that although the original outputs of the channels have a phase lag between them which is a characteristic of the channel filterbank, the three pulse streams in Figure 4c have been aligned. This is an automatic result of the way in which the stabilised image generators work because the contents of the buffers which are read by the summator (4) will always be read from a peak. This is because the reading of the contents of the buffer is instigated by the detection of a peak by the peak detector.
  • the pulse streams of the eighth, fourth and second harmonics shown in Figure 4c are the pulse streams which are input into the first inputs of the respective summators (4).
  • FIG 4d shows the stabilised images or representations of each harmonic.
  • This stabilised image is the output of the summator (4) for each channel.
  • the stabilised image has been achieved by summing the most recent pulse stream read from the buffer (1) with the attenuated stabilised image formed from the previous pulse streams read from the buffer (1). It may be seen that for the eighth harmonic an extra small peak has appeared in the stabilised image. This is because the peak detector may not always detect the major peak in the pulse stream. As is shown in Figure 4b, at the second cycle of the pulse stream, the peak detector triggered at a minor peak.
  • the stabilised image output from the summator (4) may then be input into a contour extractor (7) although this is not necessary.
  • the contour extractor (7) temporally integrates over each of the stabilised image outputs to form a frequency contour and the ordered sequences of these contours forms a spectrogram.
  • the formation of a spectrogram has been a traditional way of analysing non-sinsoidal waveforms but by delaying the formation of the spectrogram until after the formation of the stabilised image alot of noise and unwanted variation in the information is removed.
  • the resultant spectrogram formed after the formation of the stabilised image is a much clearer representation than a spectrogram formed directly from the outputs of the channels of the filterbank.
  • the integration time of the contour extractor (7) may be pre-set between the region, for example, 20 ms to 40 ms. If a pre-set integration time is used then the window over which the integration takes place should not be rectangular but should decrease from left to right across the window becausethe stabilised image is more variable to the right hand edges as is described later. Preferably however pitch information is extracted from the stabilised image so that the integration time may be set at one or two cycles of the waveform and so integration is synchronised to the pitch period.
  • the buffer (1) when used to generate a stabilised image has a perfect memory which is transparent in that the information contained in the buffer (1) is only the most recent 20 ms of the pulse stream received. Furthermore, the transfer of information from the buffer (1) to the first input of the summator (4) is instantaneous and does not involve any form of degeneration of the information.
  • the peak detector (2) may instead detect peaks in the pulse stream from the filter channel at the same time as the pulse stream is input into the buffer (4). On detection of a peak, the subsequent pulse stream for the next 20 ms is read by the first input of the summator (4) from the buffer (1). Otherwise the stabilised image generator acts in the same way as in the previous example.
  • the buffer (1) is not used and instead on detection of a peak by the peak detector (2), the gate (3) is opened to allow the pulse stream from the filter channel to be input directly into the first input of the summator (4).
  • the peak detector (2) issues a trigger within 20 ms of the last trigger then further channels to the first input of the summator (4) are required.
  • the gate (3) opens so that the pulse stream from the channel filter is input into the first input of the summator (4) for the next 20 ms.
  • the gate (3) opens a further channel to the first input of the summator (4) so that the pulse stream may be input into the summator (4) for the next 20 ms.
  • Information in the form of two pulse streams are therefore input, in parallel, into the first input of the summator (4).
  • the pulse stream in each channel of the first input of the summator (4) will be summed by the summator (4) with the pulse stream in any other channels of the first input to the summator (4) along with the pulse stream input into the second input of the summator (4) from the decay device (6).
  • individual peaks may contribute more than once to the stabilised image at different points determined by the temporal distance between the peak and the peaks on which successive triggering has occured. This will increase the averaging or smearing properties of the stabilised image generation mechanism and will increase the effective integration time.
  • FIG. 5 A further method of stabilised image generation is shown in Figure 5.
  • the pulse stream from the output of the filter channel is input directly into the first input of the summator (4) on detection of a major peak by the peak detector (2) and issuance of a trigger from the peak detector (2).
  • the buffer (1) in this method and, unlike the previous examples, instead of the pulse stream from the output of the filter channel being supplied in segments of 20 ms the pulse stream is supplied to the summator (4) until a further trigger is issued by the peak detector (2) on detection of the next major peak in the pulse stream.
  • the summator (4) no longer sums 20 ms segments of the pulse stream from the filter channel.
  • the segments of the pulse stream being summed are variable depending upon the length of time since the last trigger.
  • the pulse streams to the righthand side of the stabilised image drop away because summation of the stabilised image on the right hand side with more recent pulse stream segments will not necessarily occur each time a trigger is issued because a further trigger may issue before the segment is large enough to cause integration of the latter half of the stabilised image.
  • the stabilised image produced by the stabilised image generator remains the same and stationary. If the waveform from the filter channel changes as shown in Figures 2 and 3 where the pitch glides smoothly from a first pitch to a second higher pitch then the stabilised image will produce a smooth transition from the first pitch to the second pitch corresponding to the changes in the waveform.
  • the stabilised image retains information on the major characteristics of the waveform it represents and avoids substantial loss of information on the waveform itself but avoids interframe variability of the type which would confuse and complicate subsequent analysis of the waveform.
  • the apparatus and methods outlined above which can be used to distinguish between periodic and aperiodic sound signals are particularly applicable to speech recognition systems.
  • speech recognition systems By their use the efficiency with which speech features can be extracted from an acoustic waveform may be enhanced such that speech recognition may be used even on small computers and dictating machines for example so that a user can input commands, programs and text directly by the spoken word without the need of a keyboard.
  • a speech recognition machine is a system for capturing speech from the surrounding air and producing an ordered record of the words carriedby the acoustic wave.
  • the main components of such a device are: 1) a filterbank which divides the acoustic wave into frequency channels, 2) a set of devices that process the information in the frequency channels to extract pitch and other speech features and 3) a linguistic processor that analyses the features in conjunction with linguistic and possibly semantic knowledge to determine what was originally said.
  • FIG. 6 a schematic diagram of a speech recognition system is shown. It may be seen that the generation of the stabilised image of the acoustic wave occurs approximately half way in the second section of the speech recognition system where the analysis of the sounds takes place. The resultant information then being supplied to the linguistic processor section of the speech recognition system.
  • the voiced parts of speech are produced by the vibration of the air column in the throat and mouth by the opening and closing of the vocal chords.
  • the resultant voiced sounds are periodic in nature, the pitch of the sound being the frequency of the glottal stops.
  • Each vowel sound also has a distinctive arrangement of four formants which are dominant modulated harmonics of the pitch of the vowel sound and the relative frequencies of the four formants are not only characteristic of the vowel sound itself but are also characteristic of the speaker.
  • Integration of the sound information is not only important for the analysis of the sound itself but is also necessary so that the output data rate is not too high to support a real-time speech recognition system.
  • the integration time is required to be as long as possible because longer integration times reduce the output data rate and reduce the inter-frame variability in the output record. Both of these reductions in turn reduce the amount of computation required to extract speech features or speech events from the output record, provided the record contains the essential information.
  • it is important to preserve the temporal acuity required for the analysis of voice characteristics.
  • the integration time It is important not to make the integration time so long that it combines the end of one speech event with the start of the next, and so produces an output vector containing average values that are characteristic of neither of the events. Similarly, if the integration time is too long, it will obscure the motion of speech features, because the output vector summarises all of the energy in one frequency band in one single number, and the fact that the frequency was changing during the interval is lost. Thus the integration time must be short enough that it does not combine speech events nor obscure the motion of the speech event.
  • FIG. 6 shows schematically a speech recognition system incorporating a bank of stabilised image generators as described above in which the stabilised image generators carry out triggered integration on the input information on the sound to be analysed.
  • the speech recognition system receives a speech wave (8) which is input into a bank of bandpass channel filters (9).
  • the bank of bandpass channel filters (9) provides 24 frequency channels which vary from a low frequency of 100Hz to a high frequency of 3700Hz. Of course more channel filters over a much wider or narrower range of frequencies could also be used.
  • the signals from all these channels are then input into a bank of adaptive threshold devices (10).
  • This adaptive threshold apparatus (10) compresses and rectifies the input information and also acts to sharpen characteristic features of the input information and reduce the effects of 'noise'.
  • the output generated in each channel by the adaptive threshold apparatus (10) provides information on the major peak formations in the waveform transmitted by each of the filter channels in the bank (9).
  • the information is then fed to a bank of stabilised image generators (11).
  • the stabilised image generators adapt the incoming information by triggered integration of the information in the form of pulse streams to produce stabilised representations or images of the input pulse streams.
  • the stabilised images of the pulse streams are then input into a bank of spiral periodicity detectors (12) which detect periodicity in the input stabilised image and this information is fed into the pitch extractor (13).
  • the pitch extractor (13) establishes the pitch of the speech wave (8) and inputs this information into an auditory feature extractor (15).
  • the bank of stabilised image generators (11) also input into a timbre extractor (14).
  • the timbre extractor (14) also inputs information regarding the timbre of the speech wave (8) into the auditory feature extractor (15).
  • the bank of adaptive threshold devices (10) may input information directly into the extractor (15).
  • the auditory feature extractor (15), a syntactic processor (16) and a semantic processor (17) each provide inputs into a linguistic processor (18) which in turn provides an output (19) in the form of an ordered record of words.
  • the pitch extractor (13) may also be used to input information regarding the pitch of the speech wave back into the contour extractor (7) in order that integration of the stabilised images of the waveforms in each of the channels is carried out in response to the pitch of the speech wave and not at a pre-set time interval.
  • the spiral periodicity detector (12) has been described in GB2169719 and will not be dealt with further here.
  • the auditory feature extractor (15) may incorporate a memory device providing templates of various timbre arrays. It also receives an indication of any periodic features detected by the pitch extractor (13). It will be appreciated that the inputs to the auditory feature extractor (15) have a spectral dimension and so the feature extractor can make vowel distinctions on the basis of formant information like any other speech system. Similarly the feature extractor can distinguish between fricatives like /f/ and /s/ on a quasi-spectral basis.
  • One of the advantages of the current arrangement is that temporal information is retained in the frequency channels when integration occurs.
  • the linguistic processor (18) derives an input from the auditory feature extractor (15) as well as an input from the syntactic processor (16) which stores rules of language and imposes restrictions to help avoid ambiguity.
  • the processor (18) also receives an input from the semantic processor (17) which imposes restrictions dependent on context so as to help determine particular interpretations depending on the context.
  • the units (10), (11), (12), (13), and (14) may each comprise a programmed computing device arranged to process pulse signals in accordance with the program.
  • the feature extractor (15), and processors (16), (17), (18) and (19) may each comprise a programmed computer or be provided in a programmed computer with memory means for storing any desired syntax or semantic rules and template for use in timbre extraction.

Landscapes

  • Engineering & Computer Science (AREA)
  • Multimedia (AREA)
  • Human Computer Interaction (AREA)
  • Health & Medical Sciences (AREA)
  • Audiology, Speech & Language Pathology (AREA)
  • Computational Linguistics (AREA)
  • Physics & Mathematics (AREA)
  • Signal Processing (AREA)
  • Acoustics & Sound (AREA)
  • Data Mining & Analysis (AREA)
  • Quality & Reliability (AREA)
  • Image Analysis (AREA)
  • Measurement Of Mechanical Vibrations Or Ultrasonic Waves (AREA)
  • Measurement And Recording Of Electrical Phenomena And Electrical Characteristics Of The Living Body (AREA)
  • Electrophonic Musical Instruments (AREA)
  • Exposure Control For Cameras (AREA)
  • Ultra Sonic Daignosis Equipment (AREA)

Abstract

PCT No. PCT/GB90/00767 Sec. 371 Date Jan. 25, 1993 Sec. 102(e) Date Jan. 25, 1993 PCT Filed May 17, 1990 PCT Pub. No. WO90/14656 PCT Pub. Date Nov. 29, 1990.Peaks are detected in the waveform and in response to the detection of peaks, successive segments of the waveform are sampled. The successive segments sampled are then summed with previously summed segments to produce a stabilized image of the waveform. The generation of the stabilized image is a data-driven process and one which is sensitive and responsive to periodic characteristics of the waveform and hence is particularly useful in the analysis of sound waves and in speech recognition systems.

Description

  • The invention relates to apparatus and methods for the generation of stabilised images from waveforms. It is particularly applicable to the analysis of non-sinusoidal waveforms which are periodic or quasi-periodic.
  • Analysis of non-sinusoidal waveforms is particularly applicable to sound waves and to speech recognition systems. Some speech processors begin the analysis of a speech wave by dividing the speech wave into separate frequency channels, either using Fourier Transform methods or a filter bank that mimics that encountered in the human auditory system to a greater or lesser degree. This is done in an attempt to make the speech recognition system noise resistant.
  • In the Fourier Transform method small segments of the wave are transformed successively from the time domain to the frequency domain, and the components in the resulting spectrum are analysed. This approach is relatively economical, but it has the disadvantage that it destroys the fine grain temporal information in the speech wave before it has been completely analysed.
  • In the filter bank method the speech wave is divided into channels by filters operating in the time domain, and the result is a set of waveforms each of which carries some portion of the original speech information. The temporal information in each channel is analysed separately and is usually divided into segments and an energy value for each segment determined so that the output of the filter bank is converted into a temporal sequence of energy values. The segment duration is typically in the range 10-40 ms. The integration is insensitive to periodicity in the information in the channel and again fine grain temporal information in the speech wave is destroyed before it has been completely analysed. At the same time with regard to detecting signals in noise, the segment durations referred to above are too short for sufficient integration to take place.
  • Preferably the temporal integration of a non-sinusoidal waveform is a data-driven process and one which is sensitive and responsive to periodic characteristics of the waveform.
  • Although the invention may be applied to a variety of waves or mechanical vibrations, the present invention is particularly suited to the analysis of sound waves. The invention is applicable to the analysis of sound waves representing musical notes or speech. In the case of speech the invention is particularly useful for a speech recognition system in which it may be used to assist pitch synchronous temporal integration and to distinguish between periodic signals representing voiced parts of speech and aperiodic signals which may be caused by noise.
  • The invention may be used to assist pitch synchronous temporal integration generating a stabilised image or representation of a waveform without substantial loss of temporal resolution. The stabilised image of a waveform referred to herein is a representation of the waveform which retains all the important temporal characteristics of the waveform and is achieved through triggered temporal integration of the waveform as described herein.
  • The present invention seeks to provide apparatus and methods for the generation of a stabilised image from a waveform using a data-driven process and one which is sensitive and responsive-to periodic characteristics of the waveform.
  • The present invention provides a method of generating a stabilised image from a waveform, which method comprises detecting peaks in said waveform, in response to detecting peaks sampling successive time extended segments of said waveform, and forming a summation output by summing first signals representing each successive segment with second signals representing an attenuated summation output formed by previous segments of said waveform, whereby said summation output forms a stabilised image of said waveform.
  • The present invention further provides a method wherein the summation output is reduced by time dependant attentuation to form the attenuated summation output. In addition preferably a first limit of the time extended segments of said waveform is determined by the detection of peaks in said waveform and either a second limit of the time extended segments of said waveform is a predetermined length of time after the first limit of the time extended segments of said waveform or a second limit of the time extended segments of said waveform is determined by the detection of peaks in said waveform.
  • In addition the present invention provides for the analysis of a non-sinusoidal sound wave a method which further includes the spectral resolution of a waveform into a plurality of filtered waveforms each filtered waveform independantly having a stabilised image generated. Preferably said method further comprises the extraction of periodic characteristics of the sound wave and the extraction of timbre characteristics of the sound wave.
  • A second aspect of the present invention provides apparatus for generating a stabilised image from a waveform comprising (a) a peak detector for receiving and detecting peaks in said waveform, (b) means for sampling successive time extended segments of said waveform, said sampling means being coupled to said peak detector, (c) summing means for summing first signals representing each successive time extended segment with second signals to form a summation output, said second signals representing an attenuated summation output, said summing means being coupled to said sampling means, and (d) feedback means for attenuating said summation output to derive said second signals from said summation output, said feedback means being coupled to said summing means, whereby said summation output forms a stabilised image of said waveform.
  • Furthermore the present invention provides speech recognition apparatus including apparatus as described above together with means for providing auditory feature extraction from analysis of the filtered waveforms together with syntactic and semantic processor means providing syntactic and semantic limitations for use in speech recognition of the sound wave.
  • Embodiments of the invention will now be described by way of example only and with reference to the accompanying drawings, in which:
    • Figure 1 is a block diagram of apparatus for generation of a stabilised image from a waveform according to the invention;
    • Figure 2 shows a subset of seven driving waves derived by spectral analysis of a sound wave which starts with a first pitch and then glides quickly to a second pitch;
    • Figure 3 shows the subset of the seven driving waves shown in Figure 2 in which the waves have been rectified so that only the positive half of the waves are shown;
    • Figure 4 is a schematic diagram of the temporal integration of three harmonics of a sound wave according to a first embodiment of the invention;
    • Figure 5 is a schematic diagram, similar to Figure 4, according to a further embodiment of the invention; and
    • Figure 6 is a schematic illustration of speech recognition apparatus in accordance with the invention.
  • Although these embodiments are applicable to the analysis of any oscillations which can be represented by a waveform, the description below relates more specifically to sound waves. They provide apparatus and methods for the generation of a stabilised image from a waveform by triggered temporal integration and may be used to assist in distinguishing between periodic and aperiodic waves. Periodic sound waves include those forming the vowel sounds of speech, notes of music and the purring of motors for example. Background noises like those produced by wind and rain for example are aperiodic sounds.
  • Temporal integration of a waveform is necessary when analysing the waveform in order to identify more clearly dominant characteristics of the waveform and also because without some form of integration the output data rate would be too high to support a real-time analysis of the waveform. This is of particular importance in the analysis of sound waves and speech recognition.
  • When analysing a non-sinusoidal sound wave, commonly the wave is firstly divided into separate frequency channels by using a bank of bandpass frequency filters. When analysing the sound wave by studying the resultant outputs from channels of the bank of frequency filters it is necessary that the information be processed. A number of processes are applied to the output of the channels in the form of compression, rectification and adaption on a channel by channel basis to sharpen distinctive features in the output and reduce 'noise' effects. Thus, referring to Figure 2 a subset of seven driving waves from the channels of a filterbank is shown and in Figure 3 the same sub-set of driving waves with the driving waves having been rectified and compressed is shown. The seven channel outputs shown in Figures 2 and 3 were obtained from spectral analysis of a sound wave which starts at a first pitch and glides quickly up to a second higher pitch.
  • For analysis of the sound wave it is also necessary for the output of each channel to be temporally integrated. However, such integration must occur without substantial loss of temporal resolution. Referring now to Figure 1, a schematic diagram of a stabilised image generator is shown which may be used to temporally integrate the output of a channel of a filterbank. The integration carried out by the stabilised image generator is triggered and quantised so that loss of temporal resolution from the integration is avoided. A stabilised image generator may be provided for each channel of the filterbank.
  • The stabilised image generator has a peak detector (2) coupled to sampling means in the form of a buffer (1) and a gate (3) or other means for controlling the coupling between the buffer (1) and a summator (4) or other combining means. The gate (3) and summator (4) form part of an integration device (5). The summator (4) is also coupled to a decay device (6) and forms a feedback loop with the decay device (6) in the integration device (5). Thus the output of the summator (4) is coupled to the input of the decay device (6) and the output of the decay device (6) is coupled to an input of the summator (4). The decay device derives the second input into the summator (4) from the output of the summator (4). The decay device (6) is also coupled to the peak detector (2). The summator (4) has two inputs, a first input which is coupled to the gate (3) and a second input which is coupled to the output of the decay device (6). The two inputs receive an input each from the gate (3) and the decay device (6) respectively. The two inputs received are then summed by the summator (4) and the summation output of the summator (4) is the resultant summed inputs and is a stabilised image of the input into the buffer (1). The summation output of the summator (4) is also coupled to a contour extractor (7) which temporally integrates over the stabilised image from the summator (4) and which has a separate output.
  • Referring to Figures 4 and 5, the period of a sound wave is represented schematically as a pulse stream in Figures 4a and 5a having a period of 8 ms and with just over 6 cycles shown. Figures 4b and 5b show schematically the output of three channels of a filterbank in response to the sound wave, the three channels having centre frequencies in the region of the second, fourth and eighth harmonics of the sound wave. The first pulse in each cycle is labelled with the cycle number and the harmonics are identified on the left hand edge of Figures 4b and 5b. The time axes are the same in Figures 4a, 4b, 5a and 5b.
  • Referring now to the representation of the eighth harmonic in Figure 4, the output of the channel in the form of a pulse stream or waveform is input into the stabilised image generator through the buffer (1) and separately into the peak detector (2). In this example the buffer (1) has a fixed size of 20 ms and there is a time delay mechanism whereby the peak detector (2) receives the pulse stream approximately 20 ms after the pulse stream was initially received by the buffer (1). The buffer (1) is transparent and retains the most recent 20 ms of the pulse stream received. The peak detector (2) detects major peaks in the pulse stream and on detection of a major peak issues a trigger to the gate (3). When the gate (3) receives a trigger from the peak detector (2) the gate (3) opens to allow the contents of the buffer (1) at that instant to be read by the first input of the summator (4). Once the contents of the buffer (1) has been read by the summator (4) the gate (3) closes and the process continues until a further trigger is issued from the peak detector (2) when the gate (3) opens again and so on.
  • In the summator (4) the contents of the buffer (1) read by the first input of the summator (4) is added to the input pulse stream of the second input of the summator (4). The output of the summator (4) is the resultant summed pulse stream. Initially, there is no pulse stream input to the second input of the summator (4) and the output of the summator (4) which is the summed pulse stream is the same as the pulse stream received from the buffer (1) by the first input of the summator (4). However, the second input of the summator (4) is coupled to the output of the decay device (6) and in turn the input of the decay device (6) is coupled to the output of the summator (4); thus after the initial output from the summator (4) the second input of the summator (4) has an input pulse stream which is the same as the output of the summator (4) except that the pulse stream has been attenuated.
  • The decay device (6) has a predetermined attenuation such that it is sufficiently slow that the stabilised image will produce a smooth change when there is a smooth transition in the pulse stream input into the buffer (1). If however, the periodicity of the pulse stream input into the buffer (1) remains the same the stabilised image is strengthened over an initial time period for example 30 ms and then asymptotes to a stable form over a similar time period such that the pulse stream input into the first input of the summator (4) is equal to the amount the summed pulse stream is attenuated by the decay device (6). The resultant stabilised image has a greater degree of contrast relative to the pulse stream input into the buffer. If the pulse stream into the first input of the summator (4) is set to zero then the summator (4) continues to sum the two inputs, and the stabilised image gradually decays down to zero also. The predetermined attenuation is proportional to the logarithm of the time since the last trigger was issued by the peak detector (2) and the issuance of a trigger by the peak detector (2) may be noted by the decay device (6) through its coupling with the peak detector (2) though this is not necessary.
  • The 't' marker on Figure 4b at about 20 ms indicates the detection point of the peak detector (2) relative to the pulse stream being received by the buffer (1). The contents of the buffer (1) being retained at that moment is the pulse stream appearing between the 't' marker and the far right of the diagram at 0 ms. The upward strokes on certain peaks of the pulse stream of the eighth harmonic indicate previous peaks detected for which triggers were issued by the peak detector (2). Figure 4c shows schematically the contents of the buffer (1) when the most recent trigger was issued by the peak detector (2). As may be seen by referring back to Figure 4b for the eighth harmonic the previous trigger occurred in the fourth cycles and is shown in Figure 4c. The fifth and sixth cycle of the pulse stream were also contained in the buffer (1). when the trigger was issued and they are also shown.
  • A similar process has been applied to the fourth and second harmonics each having been input into a separate stabilised image generator and Figure 4c shows the contents of three buffers for the three channels when the most recent triggers were issued by the corresponding peak detectors. It may be seen that although the original outputs of the channels have a phase lag between them which is a characteristic of the channel filterbank, the three pulse streams in Figure 4c have been aligned. This is an automatic result of the way in which the stabilised image generators work because the contents of the buffers which are read by the summator (4) will always be read from a peak. This is because the reading of the contents of the buffer is instigated by the detection of a peak by the peak detector.
  • In terms of sound analysis and in particular speech recognition it has been shown that the ear cannot distinguish between sound waves having the same harmonics but different phases between the hamonics and so such an alignment of the pulse streams is advantageous. The pulse streams of the eighth, fourth and second harmonics shown in Figure 4c are the pulse streams which are input into the first inputs of the respective summators (4).
  • Figure 4d shows the stabilised images or representations of each harmonic. This stabilised image is the output of the summator (4) for each channel. The stabilised image has been achieved by summing the most recent pulse stream read from the buffer (1) with the attenuated stabilised image formed from the previous pulse streams read from the buffer (1). It may be seen that for the eighth harmonic an extra small peak has appeared in the stabilised image. This is because the peak detector may not always detect the major peak in the pulse stream. As is shown in Figure 4b, at the second cycle of the pulse stream, the peak detector triggered at a minor peak. However, it may be seen from Figure 4d that even with this form of error the resultant stabilised image is a very accurate representation of the original pulse stream output from the channel and that such errors only introduce minor changes to the eventual stabilised image. Similarly other 'noise' effects and minor variations in the pulse stream of the channel would not substantially effect the stabilised image. Broadly speaking, the variability in the peak detector (2) causes minor broadening and flattening of the stabilised image relative to the original pulse stream.
  • The stabilised image output from the summator (4) may then be input into a contour extractor (7) although this is not necessary. The contour extractor (7) temporally integrates over each of the stabilised image outputs to form a frequency contour and the ordered sequences of these contours forms a spectrogram. The formation of a spectrogram has been a traditional way of analysing non-sinsoidal waveforms but by delaying the formation of the spectrogram until after the formation of the stabilised image alot of noise and unwanted variation in the information is removed. Thus the resultant spectrogram formed after the formation of the stabilised image is a much clearer representation than a spectrogram formed directly from the outputs of the channels of the filterbank.
  • The integration time of the contour extractor (7) may be pre-set between the region, for example, 20 ms to 40 ms. If a pre-set integration time is used then the window over which the integration takes place should not be rectangular but should decrease from left to right across the window becausethe stabilised image is more variable to the right hand edges as is described later. Preferably however pitch information is extracted from the stabilised image so that the integration time may be set at one or two cycles of the waveform and so integration is synchronised to the pitch period.
  • The buffer (1) when used to generate a stabilised image has a perfect memory which is transparent in that the information contained in the buffer (1) is only the most recent 20 ms of the pulse stream received. Furthermore, the transfer of information from the buffer (1) to the first input of the summator (4) is instantaneous and does not involve any form of degeneration of the information.
  • Alternatively it is not necessary for the peak detector (2) to be delayed relative to the buffer (1) and the peak detector (2) may instead detect peaks in the pulse stream from the filter channel at the same time as the pulse stream is input into the buffer (4). On detection of a peak, the subsequent pulse stream for the next 20 ms is read by the first input of the summator (4) from the buffer (1). Otherwise the stabilised image generator acts in the same way as in the previous example.
  • In a further alternative the buffer (1) is not used and instead on detection of a peak by the peak detector (2), the gate (3) is opened to allow the pulse stream from the filter channel to be input directly into the first input of the summator (4). In this further method if the peak detector (2) issues a trigger within 20 ms of the last trigger then further channels to the first input of the summator (4) are required. For example, if the peak detector (2) issues a trigger to the gate (3), the gate (3) opens so that the pulse stream from the channel filter is input into the first input of the summator (4) for the next 20 ms. If the peak detector (2) then issues a further trigger to the gate (3), 5 ms later, the gate (3) opens a further channel to the first input of the summator (4) so that the pulse stream may be input into the summator (4) for the next 20 ms.
  • Information in the form of two pulse streams are therefore input, in parallel, into the first input of the summator (4). The pulse stream in each channel of the first input of the summator (4) will be summed by the summator (4) with the pulse stream in any other channels of the first input to the summator (4) along with the pulse stream input into the second input of the summator (4) from the decay device (6).
  • In both of the above mentioned examples individual peaks may contribute more than once to the stabilised image at different points determined by the temporal distance between the peak and the peaks on which successive triggering has occured. This will increase the averaging or smearing properties of the stabilised image generation mechanism and will increase the effective integration time.
  • A further method of stabilised image generation is shown in Figure 5. With this method the pulse stream from the output of the filter channel is input directly into the first input of the summator (4) on detection of a major peak by the peak detector (2) and issuance of a trigger from the peak detector (2). No use is made of the buffer (1) in this method and, unlike the previous examples, instead of the pulse stream from the output of the filter channel being supplied in segments of 20 ms the pulse stream is supplied to the summator (4) until a further trigger is issued by the peak detector (2) on detection of the next major peak in the pulse stream. Thus the summator (4) no longer sums 20 ms segments of the pulse stream from the filter channel. The segments of the pulse stream being summed are variable depending upon the length of time since the last trigger.
  • Thus, it may be seen in Figure 5c that since the last trigger, only just over one cycle has been supplied to the summator (4) for the eigth harmonic, almost two cycles for the fourth harmonic and two cycles for the second harmonic. Hence the segment time length is reduced in this third method for the purpose of integration. Furthermore any one peak in the pulse stream is integrated only once instead of possibly two or three times as in the previous examples. Figure 5d shows schematically the resultant stabilised image for each harmonic and again it may be seen that even taking into account variability in the issuance of the trigger by the peak detection (2) the stabilised images retain the overall features of the pulse streams from the filter channels. With reference to the second harmonic in Figure 5d the discontinuity in the peak at 8 ms shows the formation of the stabilised image in progress. Hence from 0 to 8 ms in Figure 5d for the second harmonic the most recent pulse stream has been summed with the attenuated pulse stream from the decay device (6) whereas from 8 ms onwards the previous stabilised image is shown.
  • The pulse streams to the righthand side of the stabilised image drop away because summation of the stabilised image on the right hand side with more recent pulse stream segments will not necessarily occur each time a trigger is issued because a further trigger may issue before the segment is large enough to cause integration of the latter half of the stabilised image.
  • In all of the above examples if the waveform from the filter channel remains the same, then the stabilised image produced by the stabilised image generator remains the same and stationary. If the waveform from the filter channel changes as shown in Figures 2 and 3 where the pitch glides smoothly from a first pitch to a second higher pitch then the stabilised image will produce a smooth transition from the first pitch to the second pitch corresponding to the changes in the waveform. Thus the stabilised image retains information on the major characteristics of the waveform it represents and avoids substantial loss of information on the waveform itself but avoids interframe variability of the type which would confuse and complicate subsequent analysis of the waveform.
  • The apparatus and methods outlined above which can be used to distinguish between periodic and aperiodic sound signals are particularly applicable to speech recognition systems. By their use the efficiency with which speech features can be extracted from an acoustic waveform may be enhanced such that speech recognition may be used even on small computers and dictating machines for example so that a user can input commands, programs and text directly by the spoken word without the need of a keyboard. A speech recognition machine is a system for capturing speech from the surrounding air and producing an ordered record of the words carriedby the acoustic wave. The main components of such a device are: 1) a filterbank which divides the acoustic wave into frequency channels, 2) a set of devices that process the information in the frequency channels to extract pitch and other speech features and 3) a linguistic processor that analyses the features in conjunction with linguistic and possibly semantic knowledge to determine what was originally said.
  • With reference to Figure 6 a schematic diagram of a speech recognition system is shown. It may be seen that the generation of the stabilised image of the acoustic wave occurs approximately half way in the second section of the speech recognition system where the analysis of the sounds takes place. The resultant information then being supplied to the linguistic processor section of the speech recognition system.
  • The most important parts of speech for speech recognition purposes are the voiced parts of speech particularly the vowel sounds. The voiced sounds are produced by the vibration of the air column in the throat and mouth by the opening and closing of the vocal chords. The resultant voiced sounds are periodic in nature, the pitch of the sound being the frequency of the glottal stops. Each vowel sound also has a distinctive arrangement of four formants which are dominant modulated harmonics of the pitch of the vowel sound and the relative frequencies of the four formants are not only characteristic of the vowel sound itself but are also characteristic of the speaker. For an effective speech recognition system it is necessary that as much information about the pitch and the formants of the voiced sounds is retained whilst also ensuring that other 'noise' does not interfer with the clear identification of the pitch and formants.
  • Integration of the sound information is not only important for the analysis of the sound itself but is also necessary so that the output data rate is not too high to support a real-time speech recognition system. However, there are a number of issues that arise when an attempt is made to choose the optimum integration time for a traditional speech system which segments either the speech wave itself or the filberbank outputs into a sequency of examples all of the same duration. Generally the integration time is required to be as long as possible because longer integration times reduce the output data rate and reduce the inter-frame variability in the output record. Both of these reductions in turn reduce the amount of computation required to extract speech features or speech events from the output record, provided the record contains the essential information. At the same time, it is important to preserve the temporal acuity required for the analysis of voice characteristics. It is important not to make the integration time so long that it combines the end of one speech event with the start of the next, and so produces an output vector containing average values that are characteristic of neither of the events. Similarly, if the integration time is too long, it will obscure the motion of speech features, because the output vector summarises all of the energy in one frequency band in one single number, and the fact that the frequency was changing during the interval is lost. Thus the integration time must be short enough that it does not combine speech events nor obscure the motion of the speech event. There is the added risk that, whatever the integration time, by using a fixed integration time, whenever the pitch of the sound event and the integration time differ, the output record will contain inter-frame variability that is not a characteristic of the speech itself - but is variability that is generated by the interaction of the sound event with the analysis integration time. Thus use of a variable, triggered integration time as proposed above avoids these problems particularly in relation to speech recognition systems.
  • Figure 6 shows schematically a speech recognition system incorporating a bank of stabilised image generators as described above in which the stabilised image generators carry out triggered integration on the input information on the sound to be analysed. The speech recognition system receives a speech wave (8) which is input into a bank of bandpass channel filters (9). The bank of bandpass channel filters (9) provides 24 frequency channels which vary from a low frequency of 100Hz to a high frequency of 3700Hz. Of course more channel filters over a much wider or narrower range of frequencies could also be used. The signals from all these channels are then input into a bank of adaptive threshold devices (10). This adaptive threshold apparatus (10) compresses and rectifies the input information and also acts to sharpen characteristic features of the input information and reduce the effects of 'noise'. The output generated in each channel by the adaptive threshold apparatus (10) provides information on the major peak formations in the waveform transmitted by each of the filter channels in the bank (9). The information is then fed to a bank of stabilised image generators (11). The stabilised image generators adapt the incoming information by triggered integration of the information in the form of pulse streams to produce stabilised representations or images of the input pulse streams. The stabilised images of the pulse streams are then input into a bank of spiral periodicity detectors (12) which detect periodicity in the input stabilised image and this information is fed into the pitch extractor (13). The pitch extractor (13) establishes the pitch of the speech wave (8) and inputs this information into an auditory feature extractor (15).
  • The bank of stabilised image generators (11) also input into a timbre extractor (14). The timbre extractor (14) also inputs information regarding the timbre of the speech wave (8) into the auditory feature extractor (15). In addition, the bank of adaptive threshold devices (10) may input information directly into the extractor (15). The auditory feature extractor (15), a syntactic processor (16) and a semantic processor (17) each provide inputs into a linguistic processor (18) which in turn provides an output (19) in the form of an ordered record of words.
  • The pitch extractor (13) may also be used to input information regarding the pitch of the speech wave back into the contour extractor (7) in order that integration of the stabilised images of the waveforms in each of the channels is carried out in response to the pitch of the speech wave and not at a pre-set time interval.
  • The spiral periodicity detector (12) has been described in GB2169719 and will not be dealt with further here. The auditory feature extractor (15) may incorporate a memory device providing templates of various timbre arrays. It also receives an indication of any periodic features detected by the pitch extractor (13). It will be appreciated that the inputs to the auditory feature extractor (15) have a spectral dimension and so the feature extractor can make vowel distinctions on the basis of formant information like any other speech system. Similarly the feature extractor can distinguish between fricatives like /f/ and /s/ on a quasi-spectral basis. One of the advantages of the current arrangement is that temporal information is retained in the frequency channels when integration occurs.
  • The linguistic processor (18) derives an input from the auditory feature extractor (15) as well as an input from the syntactic processor (16) which stores rules of language and imposes restrictions to help avoid ambiguity. The processor (18) also receives an input from the semantic processor (17) which imposes restrictions dependent on context so as to help determine particular interpretations depending on the context.
  • In the above example, the units (10), (11), (12), (13), and (14) may each comprise a programmed computing device arranged to process pulse signals in accordance with the program. The feature extractor (15), and processors (16), (17), (18) and (19) may each comprise a programmed computer or be provided in a programmed computer with memory means for storing any desired syntax or semantic rules and template for use in timbre extraction.

Claims (19)

  1. A method of generating a stabilised image from a waveform, which method comprises detecting peaks in said waveform, in response to detecting peaks sampling successive time extended segments of said waveform, and forming a summation output by summing first signals representing each successive segment with second signals representing an attenuated summation output formed by previous segments of said waveform, , whereby said summation output forms a stabilised image of said waveform.
  2. A method as claimed in Claim 1, wherein the summation output is reduced by time dependant attenuation to form the attenuated summation output.
  3. A method as claimed in Claim 2, wherein the time dependant attenuation is proportional to the time between successive sampling of time extended segments of said waveform.
  4. A method as claimed in Claim 1, wherein a first limit of the time extended segments of said waveform is determined by the detection of peaks in said waveform.
  5. A method as claimed in Claim 4, wherein a second limit of the time extended segments of said waveform is a predetermined length of time after the first limit of the time extended segments of said waveform.
  6. A method as claimed in Claim 4, wherein a second limit of the time extended segments of said waveform is determined by the detection of peaks in said waveform.
  7. A method as claimed in Claim 1 for the analysis of a non-sinusoidal sound wave, wherein said method further comprises the spectral resolution of the sound wave into a plurality of filtered waveforms each filtered waveform independantly having a stabilised image generated according to the method as claimed in Claim 1.
  8. A method as claimed in Claim 7, wherein pulse streams representing the major peaks in each of the filtered waveforms are generated.
  9. A method as claimed in Claim 7, wherein said method further comprises temporal integration of each of the stabilised images of said filtered waveforms to form a stabilised frequency contour across all channels of the filtered waveforms.
  10. A method as claimed in Claim 7, wherein said method further comprises the extraction of periodic characteristics of the sound wave.
  11. A method as claimed in Claim 7, wherein said method further comprises the extraction of timbre characteristics of the sound wave.
  12. Apparatus for generating a stabilised image from a waveform, comprising (a) a peak detector (2) for receiving and detecting peaks in said waveform, (b) means (3) for sampling successive time extended segments of said waveform, said sampling means (3) being coupled to said peak detectors (2), (c) summing means (4) for summing first signals representing each successive time extended segment with second signals to form a summation output, said second signals representing an attenuated summation output, said summing means (4) being coupled to said sampling means (3), and (d) feed back means (6) for attenuating said summation output to derive said second signals from said summation output, said feed back means (6) being coupled to said summing means (4), whereby said summation output forms a stabilised image of said waveform.
  13. Apparatus as claimed in Claim 12, wherein said sampling means (3) includes gate means (3) coupled to said peak detector (2) and said summing means (4), said time extended segments of said waveform being sampled by operation of said gate means (3) in response to the detection of peaks by the peak detector (2).
  14. Apparatus as claimed in Claim 12, wherein there is further provided a buffer (1) to receive said waveform and to retain a record of time extended segments of said waveform, the buffer (1) being coupled to said sampling means (3).
  15. Apparatus as claimed in Claim 12 arranged for the analysis of a non-sinusoidal sound wave, the apparatus further comprising filtering means (9) for the spectral resolution of said sound wave into a plurality of filtered waveforms together with means (11) for generating a stabilised image of each of the filtered waveforms as claimed in Claim 12.
  16. Apparatus as claimed in Claim 15, wherein there is further provided means to form a pulse stream representing the major peaks in each of the filtered waveforms.
  17. Apparatus as claimed in Claim 15, wherein there is further provided periodicity detectors (12) arranged to detect and extract information regarding periodic characteristics of the sound wave being analysed.
  18. Apparatus as claimed in Claim 15, wherein there is further provided a timbre extractor (14) for the extraction of information from the pulse streams regarding the timbre of the sound wave being analysed.
  19. Speech recognition apparatus including apparatus according to Claim 12 together with means (15) for providing auditory feature extraction from analysis of the filtered waveforms together with syntactic (16) and semantic (17) processor means providing syntactic and semantic limitations for use in speech recognition of the sound wave.
EP90907345A 1989-05-18 1990-05-17 Apparatus and methods for the generation of stabilised images from waveforms Expired - Lifetime EP0472578B1 (en)

Applications Claiming Priority (3)

Application Number Priority Date Filing Date Title
GB8911374 1989-05-18
GB8911374A GB2232801B (en) 1989-05-18 1989-05-18 Apparatus and methods for the generation of stabilised images from waveforms
PCT/GB1990/000767 WO1990014656A1 (en) 1989-05-18 1990-05-17 Apparatus and methods for the generation of stabilised images from waveforms

Publications (2)

Publication Number Publication Date
EP0472578A1 EP0472578A1 (en) 1992-03-04
EP0472578B1 true EP0472578B1 (en) 1996-03-13

Family

ID=10656926

Family Applications (1)

Application Number Title Priority Date Filing Date
EP90907345A Expired - Lifetime EP0472578B1 (en) 1989-05-18 1990-05-17 Apparatus and methods for the generation of stabilised images from waveforms

Country Status (7)

Country Link
US (1) US5422977A (en)
EP (1) EP0472578B1 (en)
JP (1) JPH04505369A (en)
AT (1) ATE135485T1 (en)
DE (1) DE69025932T2 (en)
GB (1) GB2232801B (en)
WO (1) WO1990014656A1 (en)

Families Citing this family (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US5933808A (en) * 1995-11-07 1999-08-03 The United States Of America As Represented By The Secretary Of The Navy Method and apparatus for generating modified speech from pitch-synchronous segmented speech waveforms
US6112169A (en) * 1996-11-07 2000-08-29 Creative Technology, Ltd. System for fourier transform-based modification of audio
US6055053A (en) * 1997-06-02 2000-04-25 Stress Photonics, Inc. Full field photoelastic stress analysis
US6182042B1 (en) 1998-07-07 2001-01-30 Creative Technology Ltd. Sound modification employing spectral warping techniques
US6675140B1 (en) 1999-01-28 2004-01-06 Seiko Epson Corporation Mellin-transform information extractor for vibration sources
JP4505899B2 (en) * 1999-10-26 2010-07-21 ソニー株式会社 Playback speed conversion apparatus and method
CH695402A5 (en) * 2000-04-14 2006-04-28 Creaholic Sa A method for determining a characteristic data set for a sound signal.
US7346172B1 (en) 2001-03-28 2008-03-18 The United States Of America As Represented By The United States National Aeronautics And Space Administration Auditory alert systems with enhanced detectability
WO2005015543A1 (en) * 2003-08-06 2005-02-17 Frank Uldall Leonhard Method for analysing signals containing pulses
EP2406787B1 (en) * 2009-03-11 2014-05-14 Google, Inc. Audio classification for information retrieval using sparse features

Family Cites Families (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2181265A (en) * 1937-08-25 1939-11-28 Bell Telephone Labor Inc Signaling system
NL291827A (en) * 1961-03-17
US3466394A (en) * 1966-05-02 1969-09-09 Ibm Voice verification system
US4802225A (en) * 1985-01-02 1989-01-31 Medical Research Council Analysis of non-sinusoidal waveforms
JPH065451B2 (en) * 1986-12-22 1994-01-19 株式会社河合楽器製作所 Pronunciation training device

Also Published As

Publication number Publication date
JPH04505369A (en) 1992-09-17
GB8911374D0 (en) 1989-07-05
GB2232801B (en) 1993-12-22
ATE135485T1 (en) 1996-03-15
EP0472578A1 (en) 1992-03-04
DE69025932T2 (en) 1996-09-19
DE69025932D1 (en) 1996-04-18
GB2232801A (en) 1990-12-19
WO1990014656A1 (en) 1990-11-29
US5422977A (en) 1995-06-06

Similar Documents

Publication Publication Date Title
Talkin et al. A robust algorithm for pitch tracking (RAPT)
Anusuya et al. Front end analysis of speech recognition: a review
US4933973A (en) Apparatus and methods for the selective addition of noise to templates employed in automatic speech recognition systems
US5054085A (en) Preprocessing system for speech recognition
EP0054365B1 (en) Speech recognition systems
US8036891B2 (en) Methods of identification using voice sound analysis
US5913188A (en) Apparatus and method for determining articulatory-orperation speech parameters
Joshi et al. MATLAB based feature extraction using Mel frequency cepstrum coefficients for automatic speech recognition
JPH08263097A (en) Method for recognition of word of speech and system for discrimination of word of speech
D’ALESSANDRO et al. Glottal closure instant and voice source analysis using time-scale lines of maximum amplitude
EP0472578B1 (en) Apparatus and methods for the generation of stabilised images from waveforms
Athineos et al. LP-TRAP: Linear predictive temporal patterns
Patterson et al. Auditory models as preprocessors for speech recognition
US5483617A (en) Elimination of feature distortions caused by analysis of waveforms
Todd et al. Visualization of rhythm, time and metre
JPS6366600A (en) Method and apparatus for obtaining normalized signal for subsequent processing by preprocessing of speaker,s voice
Nasreen et al. Speech analysis for automatic speech recognition
Greenberg et al. The analysis and representation of speech
JPH0475520B2 (en)
Wolf Speech signal processing and feature extraction
Yegnanarayana et al. Source-system windowing for speech analysis and synthesis
Boyanov et al. Pathological voice analysis using cepstra, bispectra and group delay functions.
KUMAR High Resolution Property of Group Delay and its Application to Musical Onset Detection on Carnatic Percussion Instruments
Malbos et al. Detection of stop consonants with the wavelet transform
Ambikairajah Efficient digital techniques for speech processing.

Legal Events

Date Code Title Description
PUAI Public reference made under article 153(3) epc to a published international application that has entered the european phase

Free format text: ORIGINAL CODE: 0009012

17P Request for examination filed

Effective date: 19911112

AK Designated contracting states

Kind code of ref document: A1

Designated state(s): AT BE CH DE DK ES FR GB IT LI LU NL SE

17Q First examination report despatched

Effective date: 19940321

ITF It: translation for a ep patent filed
GRAA (expected) grant

Free format text: ORIGINAL CODE: 0009210

AK Designated contracting states

Kind code of ref document: B1

Designated state(s): AT BE CH DE DK ES FR GB IT LI LU NL SE

PG25 Lapsed in a contracting state [announced via postgrant information from national office to epo]

Ref country code: NL

Free format text: LAPSE BECAUSE OF FAILURE TO SUBMIT A TRANSLATION OF THE DESCRIPTION OR TO PAY THE FEE WITHIN THE PRESCRIBED TIME-LIMIT

Effective date: 19960313

Ref country code: LI

Free format text: LAPSE BECAUSE OF FAILURE TO SUBMIT A TRANSLATION OF THE DESCRIPTION OR TO PAY THE FEE WITHIN THE PRESCRIBED TIME-LIMIT

Effective date: 19960313

Ref country code: ES

Free format text: THE PATENT HAS BEEN ANNULLED BY A DECISION OF A NATIONAL AUTHORITY

Effective date: 19960313

Ref country code: DK

Effective date: 19960313

Ref country code: CH

Free format text: LAPSE BECAUSE OF FAILURE TO SUBMIT A TRANSLATION OF THE DESCRIPTION OR TO PAY THE FEE WITHIN THE PRESCRIBED TIME-LIMIT

Effective date: 19960313

Ref country code: BE

Effective date: 19960313

Ref country code: AT

Effective date: 19960313

REF Corresponds to:

Ref document number: 135485

Country of ref document: AT

Date of ref document: 19960315

Kind code of ref document: T

REF Corresponds to:

Ref document number: 69025932

Country of ref document: DE

Date of ref document: 19960418

ET Fr: translation filed
PG25 Lapsed in a contracting state [announced via postgrant information from national office to epo]

Ref country code: LU

Free format text: LAPSE BECAUSE OF NON-PAYMENT OF DUE FEES

Effective date: 19960531

PG25 Lapsed in a contracting state [announced via postgrant information from national office to epo]

Ref country code: SE

Effective date: 19960613

NLV1 Nl: lapsed or annulled due to failure to fulfill the requirements of art. 29p and 29m of the patents act
REG Reference to a national code

Ref country code: CH

Ref legal event code: PL

PLBE No opposition filed within time limit

Free format text: ORIGINAL CODE: 0009261

STAA Information on the status of an ep patent application or granted ep patent

Free format text: STATUS: NO OPPOSITION FILED WITHIN TIME LIMIT

26N No opposition filed
PGFP Annual fee paid to national office [announced via postgrant information from national office to epo]

Ref country code: GB

Payment date: 19990512

Year of fee payment: 10

PGFP Annual fee paid to national office [announced via postgrant information from national office to epo]

Ref country code: FR

Payment date: 19990528

Year of fee payment: 10

PGFP Annual fee paid to national office [announced via postgrant information from national office to epo]

Ref country code: DE

Payment date: 19990624

Year of fee payment: 10

PG25 Lapsed in a contracting state [announced via postgrant information from national office to epo]

Ref country code: GB

Free format text: LAPSE BECAUSE OF NON-PAYMENT OF DUE FEES

Effective date: 20000517

GBPC Gb: european patent ceased through non-payment of renewal fee

Effective date: 20000517

PG25 Lapsed in a contracting state [announced via postgrant information from national office to epo]

Ref country code: FR

Free format text: LAPSE BECAUSE OF NON-PAYMENT OF DUE FEES

Effective date: 20010131

PG25 Lapsed in a contracting state [announced via postgrant information from national office to epo]

Ref country code: DE

Free format text: LAPSE BECAUSE OF NON-PAYMENT OF DUE FEES

Effective date: 20010301

REG Reference to a national code

Ref country code: FR

Ref legal event code: ST

PG25 Lapsed in a contracting state [announced via postgrant information from national office to epo]

Ref country code: IT

Free format text: LAPSE BECAUSE OF NON-PAYMENT OF DUE FEES;WARNING: LAPSES OF ITALIAN PATENTS WITH EFFECTIVE DATE BEFORE 2007 MAY HAVE OCCURRED AT ANY TIME BEFORE 2007. THE CORRECT EFFECTIVE DATE MAY BE DIFFERENT FROM THE ONE RECORDED.

Effective date: 20050517